Startseite Pain provocation following sagittal plane repeated movements in people with chronic low back pain: Associations with pain sensitivity and psychological profiles
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Pain provocation following sagittal plane repeated movements in people with chronic low back pain: Associations with pain sensitivity and psychological profiles

  • Martin Rabey EMAIL logo , Anne Smith , Darren Beales , Helen Slater und Peter O’Sullivan
Veröffentlicht/Copyright: 1. Juli 2017
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Scandinavian Journal of Pain
Aus der Zeitschrift Scandinavian Journal of Pain Band 16 Heft 1

Abstract

Background and aims

Provocative pain responses following standardised protocols of repeated sagittal plane spinal bending have not been reported in people with chronic low back pain (CLBP). Potential differing pain responses to movement likely reflect complex sensorimotor interactions influenced by physical, psychological and neurophysiological factors. To date, it is unknown whether provocative pain responses following repeated bending are associated with different pain sensitivity and psychological profiles. Therefore the first aim of this study was to determine whether data-driven subgroups with different, clinically-important pain responses following repeated movement exist in a large CLBP cohort, specifically using a standardised protocol of repeated sagittal plane spinal bending. The second aim was to determine if the resultant pain responses following repeated movement were associated with pain and disability, pain sensitivity and psychological factors.

Methods

Clinically-important (≥2-points, 11-point numeric rating scale) changes in pain intensity following repeated forward/backward bending were examined. Participants with different provocative pain responses to forward and backward bending were profiled on age, sex, pain sensitivity, psychological variables, pain characteristics and disability.

Results

Three groups with differing provocative pain responses following repeated movements were derived: (i) no clinically-important increased pain in either direction (n = 144, 49.0%), (ii) increased pain with repeated bending in one direction only (unidirectional, n = 112, 38.1%), (iii) increased pain with repeated bending in both directions (bidirectional, n = 38, 12.9%). After adjusting for psychological profile, age and sex, for the group with bidirectional pain provocation responses following repeated spinal bending, higher pressure and thermal pain sensitivity were demonstrated, while for the group with no increase in pain, better cognitive and affective psychological questionnaire scores were evident. However, these associations between provocative pain responses following movement and pain sensitivity and psychological profiles were weak.

Conclusions

Provocative pain responses following repeated movements in people with CLBP appear heterogeneous, and are weakly associated with pain sensitivity and psychological profiles.

Implications

To date, suboptimal outcomes in studies examining exercise interventions targeting directional, movement-based subgroups in people with CLBP may reflect limited consideration of broader multidimensional clinical profiles associated with LBP.

This article describes heterogeneous provocative pain responses following repeated spinal bending, and their associated pain sensitivity and psychological profiles, in people with CLBP. These findings may help facilitate targeted management.

For people with no increase in pain, the lack of pain provocation following repeated spinal bending, in combination with a favourable psychological profile, suggests this subgroup may have fewer barriers to functional rehabilitation. In contrast, those with pain provoked by both forward and backward bending may require specific interventions targeting increased pain sensitivity and negative psychological cognitions and affect, as these may be may be important barriers to functional rehabilitation.

Keywords: Chronic low back pain; Repeated movement; Pain sensitivity; Psychological; Heterogeneous

1 Introduction

Clinicians commonly evaluate pain responses to repeated movement in people with chronic low back pain (CLBP), particularly sagittal plane spinal bending [1]. It has been reported that for some individuals, pain is not influenced by repeated movement, for some there is a unidirectional (UD) response to either repeated forward or backward bending, and for others there is a bidirectional (BD) response to both repeated flexion and extension [2, 3, 4, 5].

The classification of subgroups within the population of people with CLBP is a research priority, which may facilitate targeted management strategies and improved treatment outcomes [6, 7]. CLBP classification systems may be described as: (1) based upon clinical opinion, (2) based on theoretical models derived from experimental observation, (3) purely data driven [8]. The majority of movement- based classification systems [1, 9, 10] can be considered to be in the first two of these categories. While heterogeneous pain responses to a standardised protocol of directional repeated movements have been demonstrated [2], subgrouping based upon such movements is based upon clinical assessment underpinned by a theoretical model [1] and therefore cannot be regarded as purely data driven [8]. To date, the majority of studies examining pain responses to repeated movements have also involved samples including, or exclusively made up of, people with acute LBP +/− leg pain [11, 12, 13, 14, 15, 16, 17, 18].

Potential differing pain responses to movement, such as those described above, likely reflect complex sensorimotor interactions influenced by physical, psychological and neurophysiological factors as highlighted in recent literature [19, 20]. Investigations in people with CLBP support this premise. For example, in people with CLBP demonstrating pain provocation with repeated lifting, pain intensity has been positively associated with kinesiophobia, catastrophizing and depression [21]. People with CLBP reporting “disproportionate” pain responses to spinal movement, demonstrated greater pressure and cold pain sensitivity and higher levels of psychological distress than people with CLBP and “proportionate” pain responses [22]. Another study examining repeated lifting in people with CLBP demonstrated increasing pain intensity and pressure pain sensitivity over 25 repetitions [23].

Previously we have utilised data-driven methods to derive subgroups based upon pain sensitivity [24] and psychological factors [25] in the same CLBP cohort. Data-driven subgrouping involves statistical (broadly defined as the systematic organisation of numerical data) subgroup derivation, and does not rely upon clinical opinion or underlying theoretical models, but allows data collected from people with CLBP “speak for itself” [8].

Therefore the first aim of this study was to determine whether data-driven subgroups with different, clinically-important pain responses following repeated movement exist in a large CLBP cohort, specifically using a standardised protocol of repeated sagittal plane spinal bending. The second aim was to determine if the resultant pain responses following repeated movement were associated with pain and disability, pain sensitivity and psychological factors. To date these concepts have not been specifically investigated in the literature. This knowledge would provide increased insight to factors underlying pain responses to repeated movement in CLBP, which may enhance more specific targeted management.

2 Materials and methods

This research was approved by the Human Research Ethics Committees of Curtin University, Royal Perth Hospital, and Sir Charles Gairdner Hospital, Western Australia. All participants gave written, informed consent.

This cross-sectional study involved people with CLBP (n = 294, 57.1% female; median age 50 years), recruited via multimedia advertisements circulated throughout metropolitan and regional Western Australia (77.6%), and from private metropolitan physiotherapy clinics (20.1%), public metropolitan hospitals (1.4%); and private metropolitan pain management and general practice clinics (1.0%), between November 2012 and January 2014.

Participants contacted one researcher (MR) and were sent an inclusion/exclusion criteria questionnaire. Ambiguous responses were clarified by telephone.

Inclusion criteria were: aged 18–70 years; LBP > 3-months duration; ≥2-points on a numeric rating scale (NRS) (0–10) for pain intensity (past week); ≥5-points on the Roland Morris Disability Questionnaire (RMDQ) [26]; at least 60% LBP on the question [27]: “Which situation describes your pain over the past 4 weeks the best? 100% of the pain in the low back; 80% of the pain in the low back and 20% in the leg(s); 60% of the pain in the low back and 40% in the leg(s)”, etc.

Exclusion criteria were: previous extensive spinal surgery (>single-level fusion/discectomy), spinal surgery within the past six-months, serious spinal pathology (cancer, inflammatory arthropathy, etc.), diagnosed neurological disease, bilateral dorsal wrist/hand pain, pregnancy, inability to understand English.

A total of 586 potential participants contacted the research team, of whom 349 met the inclusion/exclusion criteria. Fifty-five of these potential participants declined completion of the baseline assessment, leaving a sample of 294 included participants.

3 Sagittal plane movement tasks

Participants performed two repeated bending tasks in the following order:

  1. Twenty forward spinal bends to pick up a pencil from the floor, and place it back down.

  2. Twenty backward spinal bends to view a marker on the ceiling behind them.

Repeated forward bending is a valid and reliable test of pain provocation for people with CLBP [28, 29]. Repeated backward bending was included as a common component of the examination for CLBP, and to determine whether pain provocation is influenced in a directional manner [1, 9, 30].

Participants could refuse to undertake these movements, or to complete 20 repetitions, should they feel their pain became too great, or feared symptom exacerbation. The number of repetitions completed was recorded.

Participants received standardised instructions:

  1. For forward bending, participants were asked to pick up a pencil on the floor in front of them (first forward bend), then place the pencil back on the floor (second forward bend). They repeated this until 20 bends were completed. Participants were told they could undertake this task however they wished, and at whatever speed they wished.

  2. For backward bending, participants were instructed to sight a ceiling marker approximately 60 cm behind them however they wished, at whatever speed they wished, without turning around, then return to neutral before repeating the task up to 20 times.

Assessment of whether repeated movement influenced participant’s perception of CLBP intensity, was undertaken by asking them to rate pain intensity on an NRS (0–10) before task commencement, then every five repetitions [21].

3.1 Profiling variables

Age and sex were collected for each participant.

Pain intensity (past week) was rated using the previously described, valid and reliable NRS [31].

Low back pain-related disability was measured using RMDQ [26], comprising 24 items, which the participant ticks to indicate items relevant to their presentation (maximum score 24 indicating high disability). Items examine effects of LBP on activities of daily living. It is valid and reliable [26, 32, 33].

Low back pain duration (months) was reported by each participant.

3.2 Pain sensitivity

For this cohort, pain sensitivity subgroups have been previously determined, using latent class analysis of quantitative sensory testing data [24]. Three subgroups were derived: cluster 1 (31.9%) was characterised by average to high temperature and pressure pain sensitivity, cluster 2 (52.0%) by average to high pressure pain sensitivity, and cluster 3 (16.0%) by low temperature and pressure pain sensitivity. Cluster membership was considered as a profiling variable.

3.3 Psychological profiles

For this cohort, subgroups with differing psychological profiles have been previously determined, using latent class analysis of a broad range of psychological data [25]. Three subgroups were derived: cluster 1 (23.5%) was characterised by low cognitive and affective questionnaire scores, with the exception of fear-avoidance beliefs, cluster 2 (58.8%) was characterised by relatively elevated thought suppression, catastrophizing and fear-avoidance beliefs, but low depression, anxiety and stress, and higher pain self-efficacy. Cluster 3 (17.7%) had the highest scores across cognitive and affective questionnaires, indicating greatest psychological distress. Cluster membership was considered as a profiling variable.

The sample size in this study, of approximately 300 participants, has been suggested to be adequate for studies involving latent class analysis [34], which was used to derive the pain sensitivity and psychological subgroups.

3.4 Statistical analysis

Missing data is detailed in Table 1. For questionnaires, data management was undertaken as in original manuscripts where described. Otherwise, the mean of other items was imputed in the case of one missing item, and the score considered missing in the case of two or more missing items.

Table 1

Profiles associated with differing provocative pain responses to repeated sagittal spinal bending.

Variable NIP (n = 144, 49.0%) UD (n = 112, 38.1%) BD (n = 38, 12.9%) p-Value
Age, years, median (IQR) (min, max) 50[a] (40, 59) (21, 69) 52[a] (39, 62) (18–70) 42[b] (29, 57) (18, 70) 0.042 [d]
Female, n(%) 72 (50.0) 71 (63.4) 25 (65.8) 0.051[f]
Pain intensity in the previous week (NRS), mean (SD) (min, max) 5.6[a] (2.0) (2, 9) 5.9[a] (1.8) (2, 10) 6.7[b] (1.6) (3, 10) 0.002 [e]
Duration of CLBP, months, median (IQR) (min, max) 120[a] (42, 264) (3, 624[g] 120[a] (48, 240) (3, 720)[h] 51[b] (24, 96) (7, 480[g] 0.001 [d]
RMDQ Score, median (IQR) (min, max) 8[a] (6, 11) (5, 20) 10[b] (7, 14) (5, 21) 9[b] (7, 13) (5, 24) 0.002 [d]
Baseline pain intensity (NRS) before commencing spinal bending, median (IQR) (min, max) 2 (1, 3) (0, 7) 2 (0, 3) (0, 8) 2 (1, 3) (−1, 5) 0.76[d]
Pain sensitivity (n (%))
1. Average to high temperature and pressure pain sensitivity 39 (27.1) 34 (30.4) 21 (55.3)[c] 0.024 [f]
2. Average to high pressure pain sensitivity 80 (55.6) 60 (53.6) 13 (34.2)
3. Low temperature and pressure pain sensitivity 25 (17.4) 18 (16.1) 4 (10.5)
Psychological profile (n (%))
1. Low cognitive and affective scores 47 (32.6)[c] 19 (17.0) 3 (7.9) 0.002 [f]
2. Relatively high cognitive scores, lower affective scores 80 (55.6) 68 (60.7) 25 (65.8)
3. High cognitive and affective scores 17 (11.8) 25 (22.3) 10 (26.3)

  1. Bold values are statistically significant.

    NIP, no increase in pain; UD, unidirectional increase in pain; BD, bidirectional increase in pain; NRS, numeric rating scale; RMDQ, Roland Morris Disability questionnaire.

Examination of pain responses following sagittal plane spinal bending was undertaken as follows: a score for change in pain intensity was determined by subtracting the participant’s score on the NRS after the last set of repetitions completed (maximum 20) from the baseline score [35]. Pain was deemed to have changed only if it changed by the MCID of ≥two-points [36]. For each individual, it was determined whether their pain intensity had changed by ≥two-points following repeated bending in neither direction (No increase in pain (NIP)), in only one direction (unidirectional (UD)) or in both directions (bidirectional (BD)). Preliminary analysis revealed ameliorative responses were relatively uncommon. Therefore participants experiencing decreases in pain with either forward or backward bending were considered to have no increase in pain in that direction for classification purposes. Subgrouping was subsequently based solely on pain provocation responses.

Unadjusted differences in profiling variables between groups with differing provocative pain responses following sagittal plane spinal bending were examined using analysis of variance for normally distributed variables, Kruskal–Wallis one-way analysis of variance for variables with skewed data, and chi-squared analysis for categorical data.

Multinomial logistic regression was used to examine multivariable associations between provocative pain response group membership (modelled as a dependent variable) and pain sensitivity/psychological cluster membership (modelled as independent variables), adjusting for age and sex.

Statistical analysis was performed using Stata 13.1 (Statacorp, TX, USA).

4 Results

For forward bending, 284 (96.6%) participants completed 20 repetitions. Those not completing all repetitions were (n (%)): 0 repetitions completed: 2 (0.7); 5 repetitions completed: 2 (0.7); 10 repetitions completed: 4 (1.4); 15 repetitions completed: 2 (0.7). For backward bending 277 (94.2%) participants completed 20 repetitions. Those not completing all repetitions were (n (%)): 0 repetitions completed: 2 (0.7); 5 repetitions completed: 7 (2.4); 10 repetitions completed: 6 (2.0); 15 repetitions completed: 2 (0.7).

Two participants declined to undertake the forward or backward bending task for fear of symptom exacerbation. For these participants these movements were assumed to be provocative.

Membership of derived subgroups was as follows: NIP 49.0% (n = 144), UD 38.1% (n = 112), BD 12.9% (n = 38) (Fig. 1).

Fig. 1 Flow chart showing three groups of varying responses following repeated spinal bending (numbers and percentages of participants).
Fig. 1

Flow chart showing three groups of varying responses following repeated spinal bending (numbers and percentages of participants).

Regarding ameliorative responses, only nineteen participants (6.5%) displayed decreases in pain intensity with backward bending of ≥two-points; while thirteen participants (4.4%) displayed decreases in pain intensity of ≥two-points with forward bending. For the 31 participants in total reporting a decrease in pain during forward and/or backward bending, eight were classified as NIP and 23 as UD pain provocation pattern.

4.1 Profiling variables

BD provocative pain responses were associated with significantly higher pain intensity and lower pain duration (Table 1). NIP was significantly associated with lower disability levels. The univariable association between differing pain provocation responses following repeated sagittal spinal bending and pain sensitivity subgroups was statistically significant (p = 0.014,Table 1), with higher than expected frequencies observed for those with BD and average to high temperature and pressure pain sensitivity. The univariable association between differing pain provocation responses following repeated sagittal spinal bending and psychological subgroups was statistically significant (p = 0.002,Table 1), with higher than expected frequencies observed for those with NIP and low cognitive and affect scores.

Table 2 presents the associations between differing pain provocation responses following repeated sagittal spinal bending and pain sensitivity subgroups, adjusted for psychological subgroup membership, and vice versa, estimated using a multinomial logistic regression model. This model was also adjusted for potential confounding by age and sex (Table 1). A fully saturated model estimating pain sensitivity*psychological subgroup interaction could not be estimated due to cells from this three-way association having very low frequency or no observations. The results from Table 2 show that average to high temperature and pressure pain sensitivity was significantly associated with BD pain provocation following repeated bending when referenced to either NIP or UD (p-value 0.012 and 0.026 respectively) after adjusting for psychological subgroup membership, age and sex. In addition, low cognitive and affective scores were significantly associated with NIP when referenced to either UD or BD pain provocation following repeated bending (p-value 0.003 and 0.019 respectively), after adjusting for pain sensitivity subgroup membership, age and sex. However, estimates of group contrasts had wide confidence intervals and associations although significant were not strong, with the pseudo R2 of the overall model (0.071) only improving by 0.048 over a model with gender and age alone (0.023).

Table 2

Relative risk ratios (95% CIs) for multivariable association of pain sensitivity cluster and psychological cluster membership with movement subgroups adjusted for age and gender.

UD vs. NIP BD vs. NIP BD vs. UD
Pain sensitivity 0.843[a] 0.012[a] 0.026[a]
1 vs. 3 0.93 (0.42–2.08) 2.32 (0.67–8.02) 2.49 (0.71–8.71)
2 vs. 3 0.82 (0.40–1.72) 0.67 (0.19–2.37) 0.82 (0.23–2.91)
1 vs. 2 1.13 (0.62–2.04) 3.44 (1.51–7.86) 3.05 (1.36–7.00)
Psychological profile 0.003[a] 0.019[a] 0.448[a]
2 vs. 1 2.35 (1.24–4.46) 5.42 (1.50–19.58) 2.30 (0.61–8.73)
3 vs. 1 4.08 (1.75–9.47) 7.29 (1.71–31.12) 1.79 (0.41–7.79)
3 vs. 2 1.73 (0.85–3.54) 1.34 (0.52–3.50) 0.78 (0.11–1.64)
Age (yrs) 1.01 (0.99–1.03) 0.98 (0.95–1.00) 0.96 (0.37–1.93)
Female sex 1.90 (1.11–3.25) 1.61 (0.72–3.61) 0.85 (0.37–1.93)

  1. Bold values are statistically significant.

    Pain sensitivity clusters: (1) Average to high temperature and pressure pain sensitivity; (2) average to high pressure pain sensitivity; (3) low temperature and pressure pain sensitivity.

    Psychological clusters: (1) Low cognitive and affect scores; (2) relatively high cognitive scores; (3) high cognitive and affect scores.

A sensitivity analysis was conducted to determine whether inclusion or exclusion of participants with ameliorative responses significantly altered the results of this study. This was not the case. For example, when participants with ameliorative pain responses were excluded from analysis the relative risk ratio (95% CIs) for pain sensitivity, UD vs. NIP, cluster 1 vs. 3 was 0.86 (0.37–2.03); while for age, BD vs. NIP it was 0.98 (0.95–1.00) (Table 2).

5 Discussion

5.1 Provocative pain responses following repeated spinal bending

This large CLBP study considered directional pain provocation responses following a standardised protocol of repeated sagittal plane bending utilising a data-driven approach The majority of previous reports of directional patterns of pain amelioration and provocation that included subjects with CLBP have been based more upon clinical examination and judgement rather than standardised testing [11, 12, 14, 16, 37, 38], possibly introducing bias [8].

Pain intensity prior to movement was similar across subgroups, indicating this was unrelated to pain provocation responses following repeated movement. The proportion of participants (10.9%) demonstrating pain amelioration with repeated spinal bending, is less than reported in a recent systematic review of centralisation and directional preferences [39]. This may reflect differences in subjects’ pain duration (acute/sub-acute LBP vs. CLBP) [39], the movement testing procedures utilised (only undertaken in standing in this study) [1], and/or use of a minimum two-point change in pain intensity for deriving subgroups in the current study.

The NIP subgroup has not been previously described. Previous studies have reported participants with a bidirectional improvement in symptoms [2] or no change in pain distribution [14, 16, 17, 18] with repeated movements, but this does not appear analagous to the NIP subgroup. The results of this study are also in contrast with studies where pain responses following repeated sagittal spinal bending were assumed to be homogeneous, reporting increased pain intensity with repeated movements [23, 35]. The proportion of participants with NIP is substantial, potentially reflecting methodological differences. Stipulation of the MCID for pain intensity of 2-points as the cut-off for subgrouping, such that people with <2-point increase in pain intensity were classified as NIP, could have a significant influence on subgrouping. The bending tasks utilised in this study did not involve external loads in addition to body weight, such that people subgrouped as NIP may have been subgrouped differently under greater load [35]. Also, participants were deliberately not instructed to move in a standardised manner, allowing various movement strategies including protective behaviours. While the frequency of protective behaviours was not different across subgroups, we cannot exclude that this subgroup may have adopted movement strategies perceived as effective in reducing pain provocation. Finally, while this subgroup did not report increased pain following every five repetitions, they may have experienced increased pain during movement, or a latent exacerbation, that was unrecorded.

NIP was associated with statistically significantly lower levels of disability, however the magnitude of the differences may not be clinically-important (Table 1) [40].The centralisation phenomenon (where spinal loading, possibly including repeated movements causes progressive, distal-to-proximal abolition of pain [1]), is generally associated with improved outcomes (and vice versa) [39]. A directional preference (where a particular direction of repeated movement improves symptoms, and vice versa [1]) appears to be a significant treatment effect modifier for directional exercise interventions [39]. No studies have shown that people with CLBP and NIP following repeated spinal bending have lower disability levels, or have a different prognosis with regard to disability than those with increased pain following repeated movement.

The BD subgroup was associated with statistically significantly higher pain intensity, however the magnitude of the differences may not be clinically-important (Table 1) [36]. Subjects in the BD subgroup were younger and had a longer duration of CLBP than the other subgroups. These associations have not been examined previously, and the implications of this finding in terms of different putative mechanisms are unclear.

These subgroups should be considered in light of strengths and limitations of the methodology in the study. Forward and backward bending were chosen because previous manuscripts have reported variable responses to these movements in people with CLBP [2, 3, 4, 5]. However, other movements such as side bending or rotation, may also have provoked pain responses, had they been examined. Further, examination of movement patterns previously associated with directional pain responses [41] were not examined. Inclusion criteria required participants having dominant LBP [27], minimizing the likelihood of radiculopathy which may also have influenced our findings compared to previous studies.

5.2 Provocative pain responses following repeated spinal bending and their relationship to pain sensitivity clusters

The examination of pain sensitivity in subgroups with differing provocative pain responses following repeated sagittal spinal bending was a novel feature of this study. BD was associated with greater relative risk ratios for average to high temperature and pressure pain sensitivity, after adjusting for psychological profile, age and sex (Table 2). This equated to those with BD having more than three times the risk of having average to high temperature and pressure pain sensitivity compared to those with NIP or UD. Since self-reported pain intensity may not be considered to have reached a clinically important difference between the subgroups, this study suggests that future investigations should consider the association between pain responses following repeated movements and pain sensitivity. Combined with elevated pain sensitivity, multidirectional pain responses to movement have previously been postulated to indicate an increased contribution of central pain mechanisms to the disorder [22, 42].

5.3 Provocative pain responses following repeated spinal bending and their relationship to psychological clusters

The examination of psychological clusters in subgroups with differing provocative pain responses following repeated sagittal spinal bending, is another novel feature of this study. NIP was associated with greater relative risk ratios for low cognitive and affective psychological scores (Table 2), after adjusting for pain sensitivity, age and sex. Those with NIP were 2.4–7.2 times more likely to have a more positive psychological cluster membership, than those with UD or BD. Given the cross sectional nature of this study, the direction of this relationship is not known, however, it suggests an interaction between psychological distress and provocative pain responses to movement [43, 44]. This is consistent with a previous report that fear of movement, which was significantly different across the three psychological clusters [25], is positively associated with pain intensity following a repeated lifting task [35].

6 Implications

While this study documented relationships between directional provocative pain responses following repeated spinal bending movements and pain sensitivity and psychological profiles, these relationships were not strong (Table 2). A BD provocative pain response does not predict with confidence that a person will have high psychological scores or elevated pain sensitivity, highlighting the danger of making clinical decisions on the basis of a single examination finding alone. This highlights the need for a flexible multidimensional framework which guides careful and systematic consideration of the relative contribution of multiple relevant factors when assessing and managing an individual with CLBP [5].

Assessment of pain responses following repeated movement has been advocated to help inform movement-based and targeted management [1]. Numerous studies have examined exercise interventions targeting directional, movement-based subgroups in people with CLBP. However, targeted management of this type has not demonstrated superiority to unmatched (exercises deemed appropriate for a different directional subgroup) or control, generalised exercise treatments [11, 45, 46, 47, 48]. Suboptimal outcomes in these studies may reflect limited consideration of broader multidimensional clinical profiles associated with the LBP presentation. There is early evidence that an intervention targeting broader multidimensional profiles alongside directional, functional movement retraining may show greater improvements in pain and disability than ‘one size fits all’ guideline based care [38].

For people with NIP, the lack of pain provocation following repeated spinal bending, in combination with a favourable psychological profile, suggests this subgroup may have fewer barriers to functional rehabilitation. In contrast, the BD subgroup may require specific interventions targeting increased pain sensitivity and negative psychological cognitions and affect, as these may be may be important barriers to functional rehabilitation.

Highlights

  • Provocative pain responses to repeated bending are heterogeneous in CLBP.

  • Bidirectional pain increases were associated with greater pain sensitivity.

  • No increase in pain was associated with low psychological questionnaire scores.

  1. Funding sources: Martin Rabey was supported by a Musculoskeletal Association of Chartered Physiotherapists Doctoral Award, Chartered Society of Physiotherapy Charitable Trust, Curtin University Postgraduate Scholarship and Australian Postgraduate Award.

    Darren Beales was supported by a National Health and Medical Research Council of Australia Early Career Research Fellowship. These funding sources had no role in study design; data collection, analysis or interpretation; in writing of this manuscript; or the decision to submit the article for publication.

  2. Ethical issues: All participants gave written informed consent. This research was approved by the Human Research Ethics Committees of Curtin University, Royal Perth Hospital, and Sir Charles Gairdner Hospital, Western Australia.

  3. Conflict of interest: The authors declare that there are no conflicts of interest relating to this manuscript.

Acknowledgements

Martin Rabey was supported by a Musculoskeletal Association of Chartered Physiotherapists Doctoral Award, Chartered Society of Physiotherapy Charitable Trust, Curtin University Postgraduate Scholarship and Australian Postgraduate Award.

Darren Beales was supported by a National Health and Medical Research Council of Australia Early Career Research Fellowship.

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Received: 2016-08-08
Revised: 2017-01-11
Accepted: 2017-01-25
Published Online: 2017-07-01
Published in Print: 2017-07-01

© 2017 Scandinavian Association for the Study of Pain

Artikel in diesem Heft

  2. Scandinavian Journal of Pain
  3. Editorial comment
  4. Glucocorticoids – Efficient analgesics against postherpetic neuralgia?
  5. Original experimental
  6. Effect of intrathecal glucocorticoids on the central glucocorticoid receptor in a rat nerve ligation model
  7. Editorial comment
  8. Important new insight in pain and pain treatment induced changes in functional connectivity between the Pain Matrix and the Salience, Central Executive, and Sensorimotor networks
  9. Original experimental
  10. Salience, central executive, and sensorimotor network functional connectivity alterations in failed back surgery syndrome
  11. Editorial comment
  12. Education and support strategies improve assessment and management of pain by nurses
  13. Clinical pain research
  14. Using education and support strategies to improve the way nurses assess regular and transient pain – A quality improvement study of three hospitals
  15. Editorial comment
  16. The interference of pain with task performance: Increasing ecological validity in research
  17. Original experimental
  18. The disruptive effects of pain on multitasking in a virtual errands task
  19. Editorial comment
  20. Analyzing transition from acute back pain to chronic pain with linear mixed models reveals a continuous chronification of acute back pain
  21. Observational study
  22. From acute to chronic back pain: Using linear mixed models to explore changes in pain intensity, disability, and depression
  23. Editorial comment
  24. NSAIDs relieve osteoarthritis (OA) pain, but cardiovascular safety in question even for diclofenac, ibuprofen, naproxen, and celecoxib: what are the alternatives?
  25. Clinical pain research
  26. Efficacy and safety of diclofenac in osteoarthritis: Results of a network meta-analysis of unpublished legacy studies
  27. Editorial comment
  28. Editorial comment on Nina Kreddig’s and Monika Hasenbring’s study on pain anxiety and fear of (re) injury in patients with chronic back pain: Sex as a moderator
  29. Clinical pain research
  30. Pain anxiety and fear of (re) injury in patients with chronic back pain: Sex as a moderator
  31. Editorial comment
  32. Intraoral QST – Mission impossible or not?
  33. Clinical pain research
  34. Multifactorial assessment of measurement errors affecting intraoral quantitative sensory testing reliability
  35. Editorial comment
  36. Objective measurement of subjective pain-experience: Real nociceptive stimuli versus pain expectation
  37. Clinical pain research
  38. Cerebral oxygenation for pain monitoring in adults is ineffective: A sequence-randomized, sham controlled study in volunteers
  39. Editorial comment
  40. Association between adolescent and parental use of analgesics
  41. Observational study
  42. The association between adolescent and parental use of non-prescription analgesics for headache and other somatic pain – A cross-sectional study
  43. Editorial comment
  44. Cancer-pain intractable to high-doses systemic opioids can be relieved by intraspinal local anaesthetic plus an opioid and an alfa2-adrenoceptor agonist
  45. Clinical pain research
  46. Spinal analgesia for severe cancer pain: A retrospective analysis of 60 patients
  47. Editorial comment
  48. Specific symptoms and signs of unstable back segments and curative surgery?
  49. Clinical pain research
  50. Symptoms and signs possibly indicating segmental, discogenic pain. A fusion study with 18 years of follow-up
  51. Editorial comment
  52. Local anaesthesia methods for analgesia after total hip replacement: Problems of anatomy, methodology and interpretation?
  53. Clinical pain research
  54. Local infiltration analgesia or femoral nerve block for postoperative pain management in patients undergoing total hip arthroplasty. A randomized, double-blind study
  55. Editorial
  56. Scientific presentations at the 2017 annual meeting of the Scandinavian Association for the Study of Pain (SASP)
  57. Abstracts
  58. Correlation between quality of pain and depression: A post-operative assessment of pain after caesarian section among women in Ghana
  59. Abstracts
  60. Dynamic and static mechanical pain sensitivity is associated in women with migraine
  61. Abstracts
  62. The number of active trigger points is associated with sensory and emotional aspects of health-related quality of life in tension type headache
  63. Abstracts
  64. Chronic neuropathic pain following oxaliplatin and docetaxel: A 5-year follow-up questionnaire study
  65. Abstracts
  66. Expression of α1 adrenergic receptor subtypes by afferent fibers that innervate rat masseter muscle
  67. Abstracts
  68. Buprenorphine alleviation of pain does not compromise the rat monoarthritic pain model
  69. Abstracts
  70. Association between pain, disability, widespread pressure pain hypersensitivity and trigger points in subjects with neck pain
  71. Abstracts
  72. Association between widespread pressure pain hypersensitivity, health history, and trigger points in subjects with neck pain
  73. Abstracts
  74. Neuromas in patients with peripheral nerve injury and amputation - An ongoing study
  75. Abstracts
  76. The link between chronic musculoskeletal pain and sperm quality in overweight orthopedic patients
  77. Abstracts
  78. Several days of muscle hyperalgesia facilitates cortical somatosensory excitability
  79. Abstracts
  80. Social stress, epigenetic changes and pain
  81. Abstracts
  82. Characterization of released exosomes from satellite glial cells under normal and inflammatory conditions
  83. Abstracts
  84. Cell-based platform for studying trigeminal satellite glial cells under normal and inflammatory conditions
  85. Abstracts
  86. Tramadol in postoperative pain – 1 mg/ml IV gave no pain reduction but more side effects in third molar surgery
  87. Abstracts
  88. Tempo-spatial discrimination to non-noxious stimuli is better than for noxious stimuli
  89. Abstracts
  90. The encoding of the thermal grill illusion in the human spinal cord
  91. Abstracts
  92. Effect of cocoa on endorphin levels and craniofacial muscle sensitivity in healthy individuals
  93. Abstracts
  94. The impact of naloxegol treatment on gastrointestinal transit and colonic volume
  95. Abstracts
  96. Preoperative downregulation of long-noncoding RNA Meg3 in serum of patients with chronic postoperative pain after total knee replacement
  97. Abstracts
  98. Painful diabetic polyneuropathy and quality of life in Danish type 2 diabetic patients
  99. Abstracts
  100. What about me?”: A qualitative explorative study on perspectives of spouses living with complex chronic pain patients
  101. Abstracts
  102. Increased postural stiffness in patients with knee osteoarthritis who are highly sensitized
  103. Abstracts
  104. Efficacy of dry needling on latent myofascial trigger points in male subjects with neck/shoulders musculoskeletal pain. A case series
  105. Abstracts
  106. Identification of pre-operative of risk factors associated with persistent post-operative pain by self-reporting tools in lower limb amputee patients – A feasibility study
  107. Abstracts
  108. Renal function estimations and dose recommendations for Gabapentin, Ibuprofen and Morphine in acute hip fracture patients
  109. Abstracts
  110. Evaluating the ability of non-rectangular electrical pulse forms to preferentially activate nociceptive fibers by comparing perception thresholds
  111. Abstracts
  112. Detection of systemic inflammation in severely impaired chronic pain patients, and effects of a CBT-ACT-based multi-modal pain rehabilitation program
  113. Abstracts
  114. Fixed or adapted conditioning intensity for repeated conditioned pain modulation
  115. Abstracts
  116. Combined treatment (Norspan, Gabapentin and Oxynorm) was found superior in pain management after total knee arthroplasty
  117. Abstracts
  118. Effects of conditioned pain modulation on the withdrawal pattern to nociceptive stimulation in humans – Preliminary results
  119. Abstracts
  120. Application of miR-223 onto the dorsal nerve roots in rats induces hypoexcitability in the pain pathways
  121. Abstracts
  122. Acute muscle pain alters corticomotor output of the affected muscle stronger than a synergistic, ipsilateral muscle
  123. Abstracts
  124. The subjective sensation induced by various thermal pulse stimulation in healthy volunteers
  125. Abstracts
  126. Assessing Offset Analgesia through electrical stimulations in healthy volunteers
  127. Abstracts
  128. Metastatic lung cancer in patient with non-malignant neck pain: A case report
  129. Abstracts
  130. The size of pain referral patterns from a tonic painful mechanical stimulus is increased in women
  131. Abstracts
  132. Oxycodone and macrogol 3350 treatment reduces anal sphincter relaxation compared to combined oxycodone and naloxone tablets
  133. Abstracts
  134. The effect of UVB-induced skin inflammation on histaminergic and non-histaminergic evoked itch and pain
  135. Abstracts
  136. Topical allyl-isothiocyanate (mustard oil) as a TRPA1-dependent human surrogate model of pain, hyperalgesia, and neurogenic inflammation – A dose response study
  137. Abstracts
  138. Dissatisfaction and persistent post-operative pain following total knee replacement – A 5 year follow-up of all patients from a whole region
  139. Abstracts
  140. Paradoxical differences in pain ratings of the same stimulus intensity
  141. Abstracts
  142. Pain assessment and post-operative pain management in orthopedic patients
  143. Abstracts
  144. Combined electric and pressure cuff pain stimuli for assessing conditioning pain modulation (CPM)
  145. Abstracts
  146. The effect of facilitated temporal summation of pain, widespread pressure hyperalgesia and pain intensity in patients with knee osteoarthritis on the responds to Non-Steroidal Anti-Inflammatory Drugs – A preliminary analysis
  147. Abstracts
  148. How to obtain the biopsychosocial record in multidisciplinary pain clinic? An action research study
  149. Abstracts
  150. Experimental neck muscle pain increase pressure pain threshold over cervical facet joints
  151. Abstracts
  152. Are we using Placebo effects in specialized Palliative Care?
  153. Abstracts
  154. Prevalence and pattern of helmet-induced headache among Danish military personnel
  155. Abstracts
  156. Aquaporin 4 expression on trigeminal satellite glial cells under normal and inflammatory conditions
  157. Abstracts
  158. Preoperative synovitis in knee osteoarthritis is predictive for pain 1 year after total knee arthroplasty
  159. Abstracts
  160. Biomarkers alterations in trapezius muscle after an acute tissue trauma: A human microdialysis study
  161. Abstracts
  162. PainData: A clinical pain registry in Denmark
  163. Abstracts
  164. A novel method for investigating the importance of visual feedback on somatosensation and bodily-self perception
  165. Abstracts
  166. Drugs that can cause respiratory depression with concomitant use of opioids
  167. Abstracts
  168. The potential use of a serious game to help patients learn about post-operative pain management – An evaluation study
  169. Abstracts
  170. Modelling activity-dependent changes of velocity in C-fibers
  171. Abstracts
  172. Choice of rat strain in pre-clinical pain-research – Does it make a difference for translation from animal model to human condition?
  173. Abstracts
  174. Omics as a potential tool to identify biomarkers and to clarify the mechanism of chronic pain development
  175. Abstracts
  176. Evaluation of the benefits from the introduction meeting for patients with chronic non-malignant pain and their relatives in interdisciplinary pain center
  177. Observational study
  178. The changing face of acute pain services
  179. Observational study
  180. Chronic pain in multiple sclerosis: A10-year longitudinal study
  181. Clinical pain research
  182. Functional disability and depression symptoms in a paediatric persistent pain sample
  183. Observational study
  184. Pain provocation following sagittal plane repeated movements in people with chronic low back pain: Associations with pain sensitivity and psychological profiles
  185. Observational study
  186. A longitudinal exploration of pain tolerance and participation in contact sports
  187. Original experimental
  188. Taking a break in response to pain. An experimental investigation of the effects of interruptions by pain on subsequent activity resumption
  189. Clinical pain research
  190. Sex moderates the effects of positive and negative affect on clinical pain in patients with knee osteoarthritis
  191. Original experimental
  192. The effects of a brief educational intervention on medical students’ knowledge, attitudes and beliefs towards low back pain
  193. Observational study
  194. The association between pain characteristics, pain catastrophizing and health care use – Baseline results from the SWEPAIN cohort
  195. Topical review
  196. Couples coping with chronic pain: How do intercouple interactions relate to pain coping?
  197. Narrative review
  198. The wit and wisdom of Wilbert (Bill) Fordyce (1923 - 2009)
  199. Letter to the Editor
  200. Unjustified extrapolation
  201. Letter to the Editor
  202. Response to: “Letter to the Editor entitled: Unjustified extrapolation” [by authors: Supp G., Rosedale R., Werneke M.]
https://doi.org/10.1016/j.sjpain.2017.01.009
Schlagwörter für diesen Artikel
Chronic low back pain; Repeated movement; Pain sensitivity; Psychological; Heterogeneous

Artikel in diesem Heft

  2. Scandinavian Journal of Pain
  3. Editorial comment
  4. Glucocorticoids – Efficient analgesics against postherpetic neuralgia?
  5. Original experimental
  6. Effect of intrathecal glucocorticoids on the central glucocorticoid receptor in a rat nerve ligation model
  7. Editorial comment
  8. Important new insight in pain and pain treatment induced changes in functional connectivity between the Pain Matrix and the Salience, Central Executive, and Sensorimotor networks
  9. Original experimental
  10. Salience, central executive, and sensorimotor network functional connectivity alterations in failed back surgery syndrome
  11. Editorial comment
  12. Education and support strategies improve assessment and management of pain by nurses
  13. Clinical pain research
  14. Using education and support strategies to improve the way nurses assess regular and transient pain – A quality improvement study of three hospitals
  15. Editorial comment
  16. The interference of pain with task performance: Increasing ecological validity in research
  17. Original experimental
  18. The disruptive effects of pain on multitasking in a virtual errands task
  19. Editorial comment
  20. Analyzing transition from acute back pain to chronic pain with linear mixed models reveals a continuous chronification of acute back pain
  21. Observational study
  22. From acute to chronic back pain: Using linear mixed models to explore changes in pain intensity, disability, and depression
  23. Editorial comment
  24. NSAIDs relieve osteoarthritis (OA) pain, but cardiovascular safety in question even for diclofenac, ibuprofen, naproxen, and celecoxib: what are the alternatives?
  25. Clinical pain research
  26. Efficacy and safety of diclofenac in osteoarthritis: Results of a network meta-analysis of unpublished legacy studies
  27. Editorial comment
  28. Editorial comment on Nina Kreddig’s and Monika Hasenbring’s study on pain anxiety and fear of (re) injury in patients with chronic back pain: Sex as a moderator
  29. Clinical pain research
  30. Pain anxiety and fear of (re) injury in patients with chronic back pain: Sex as a moderator
  31. Editorial comment
  32. Intraoral QST – Mission impossible or not?
  33. Clinical pain research
  34. Multifactorial assessment of measurement errors affecting intraoral quantitative sensory testing reliability
  35. Editorial comment
  36. Objective measurement of subjective pain-experience: Real nociceptive stimuli versus pain expectation
  37. Clinical pain research
  38. Cerebral oxygenation for pain monitoring in adults is ineffective: A sequence-randomized, sham controlled study in volunteers
  39. Editorial comment
  40. Association between adolescent and parental use of analgesics
  41. Observational study
  42. The association between adolescent and parental use of non-prescription analgesics for headache and other somatic pain – A cross-sectional study
  43. Editorial comment
  44. Cancer-pain intractable to high-doses systemic opioids can be relieved by intraspinal local anaesthetic plus an opioid and an alfa2-adrenoceptor agonist
  45. Clinical pain research
  46. Spinal analgesia for severe cancer pain: A retrospective analysis of 60 patients
  47. Editorial comment
  48. Specific symptoms and signs of unstable back segments and curative surgery?
  49. Clinical pain research
  50. Symptoms and signs possibly indicating segmental, discogenic pain. A fusion study with 18 years of follow-up
  51. Editorial comment
  52. Local anaesthesia methods for analgesia after total hip replacement: Problems of anatomy, methodology and interpretation?
  53. Clinical pain research
  54. Local infiltration analgesia or femoral nerve block for postoperative pain management in patients undergoing total hip arthroplasty. A randomized, double-blind study
  55. Editorial
  56. Scientific presentations at the 2017 annual meeting of the Scandinavian Association for the Study of Pain (SASP)
  57. Abstracts
  58. Correlation between quality of pain and depression: A post-operative assessment of pain after caesarian section among women in Ghana
  59. Abstracts
  60. Dynamic and static mechanical pain sensitivity is associated in women with migraine
  61. Abstracts
  62. The number of active trigger points is associated with sensory and emotional aspects of health-related quality of life in tension type headache
  63. Abstracts
  64. Chronic neuropathic pain following oxaliplatin and docetaxel: A 5-year follow-up questionnaire study
  65. Abstracts
  66. Expression of α1 adrenergic receptor subtypes by afferent fibers that innervate rat masseter muscle
  67. Abstracts
  68. Buprenorphine alleviation of pain does not compromise the rat monoarthritic pain model
  69. Abstracts
  70. Association between pain, disability, widespread pressure pain hypersensitivity and trigger points in subjects with neck pain
  71. Abstracts
  72. Association between widespread pressure pain hypersensitivity, health history, and trigger points in subjects with neck pain
  73. Abstracts
  74. Neuromas in patients with peripheral nerve injury and amputation - An ongoing study
  75. Abstracts
  76. The link between chronic musculoskeletal pain and sperm quality in overweight orthopedic patients
  77. Abstracts
  78. Several days of muscle hyperalgesia facilitates cortical somatosensory excitability
  79. Abstracts
  80. Social stress, epigenetic changes and pain
  81. Abstracts
  82. Characterization of released exosomes from satellite glial cells under normal and inflammatory conditions
  83. Abstracts
  84. Cell-based platform for studying trigeminal satellite glial cells under normal and inflammatory conditions
  85. Abstracts
  86. Tramadol in postoperative pain – 1 mg/ml IV gave no pain reduction but more side effects in third molar surgery
  87. Abstracts
  88. Tempo-spatial discrimination to non-noxious stimuli is better than for noxious stimuli
  89. Abstracts
  90. The encoding of the thermal grill illusion in the human spinal cord
  91. Abstracts
  92. Effect of cocoa on endorphin levels and craniofacial muscle sensitivity in healthy individuals
  93. Abstracts
  94. The impact of naloxegol treatment on gastrointestinal transit and colonic volume
  95. Abstracts
  96. Preoperative downregulation of long-noncoding RNA Meg3 in serum of patients with chronic postoperative pain after total knee replacement
  97. Abstracts
  98. Painful diabetic polyneuropathy and quality of life in Danish type 2 diabetic patients
  99. Abstracts
  100. What about me?”: A qualitative explorative study on perspectives of spouses living with complex chronic pain patients
  101. Abstracts
  102. Increased postural stiffness in patients with knee osteoarthritis who are highly sensitized
  103. Abstracts
  104. Efficacy of dry needling on latent myofascial trigger points in male subjects with neck/shoulders musculoskeletal pain. A case series
  105. Abstracts
  106. Identification of pre-operative of risk factors associated with persistent post-operative pain by self-reporting tools in lower limb amputee patients – A feasibility study
  107. Abstracts
  108. Renal function estimations and dose recommendations for Gabapentin, Ibuprofen and Morphine in acute hip fracture patients
  109. Abstracts
  110. Evaluating the ability of non-rectangular electrical pulse forms to preferentially activate nociceptive fibers by comparing perception thresholds
  111. Abstracts
  112. Detection of systemic inflammation in severely impaired chronic pain patients, and effects of a CBT-ACT-based multi-modal pain rehabilitation program
  113. Abstracts
  114. Fixed or adapted conditioning intensity for repeated conditioned pain modulation
  115. Abstracts
  116. Combined treatment (Norspan, Gabapentin and Oxynorm) was found superior in pain management after total knee arthroplasty
  117. Abstracts
  118. Effects of conditioned pain modulation on the withdrawal pattern to nociceptive stimulation in humans – Preliminary results
  119. Abstracts
  120. Application of miR-223 onto the dorsal nerve roots in rats induces hypoexcitability in the pain pathways
  121. Abstracts
  122. Acute muscle pain alters corticomotor output of the affected muscle stronger than a synergistic, ipsilateral muscle
  123. Abstracts
  124. The subjective sensation induced by various thermal pulse stimulation in healthy volunteers
  125. Abstracts
  126. Assessing Offset Analgesia through electrical stimulations in healthy volunteers
  127. Abstracts
  128. Metastatic lung cancer in patient with non-malignant neck pain: A case report
  129. Abstracts
  130. The size of pain referral patterns from a tonic painful mechanical stimulus is increased in women
  131. Abstracts
  132. Oxycodone and macrogol 3350 treatment reduces anal sphincter relaxation compared to combined oxycodone and naloxone tablets
  133. Abstracts
  134. The effect of UVB-induced skin inflammation on histaminergic and non-histaminergic evoked itch and pain
  135. Abstracts
  136. Topical allyl-isothiocyanate (mustard oil) as a TRPA1-dependent human surrogate model of pain, hyperalgesia, and neurogenic inflammation – A dose response study
  137. Abstracts
  138. Dissatisfaction and persistent post-operative pain following total knee replacement – A 5 year follow-up of all patients from a whole region
  139. Abstracts
  140. Paradoxical differences in pain ratings of the same stimulus intensity
  141. Abstracts
  142. Pain assessment and post-operative pain management in orthopedic patients
  143. Abstracts
  144. Combined electric and pressure cuff pain stimuli for assessing conditioning pain modulation (CPM)
  145. Abstracts
  146. The effect of facilitated temporal summation of pain, widespread pressure hyperalgesia and pain intensity in patients with knee osteoarthritis on the responds to Non-Steroidal Anti-Inflammatory Drugs – A preliminary analysis
  147. Abstracts
  148. How to obtain the biopsychosocial record in multidisciplinary pain clinic? An action research study
  149. Abstracts
  150. Experimental neck muscle pain increase pressure pain threshold over cervical facet joints
  151. Abstracts
  152. Are we using Placebo effects in specialized Palliative Care?
  153. Abstracts
  154. Prevalence and pattern of helmet-induced headache among Danish military personnel
  155. Abstracts
  156. Aquaporin 4 expression on trigeminal satellite glial cells under normal and inflammatory conditions
  157. Abstracts
  158. Preoperative synovitis in knee osteoarthritis is predictive for pain 1 year after total knee arthroplasty
  159. Abstracts
  160. Biomarkers alterations in trapezius muscle after an acute tissue trauma: A human microdialysis study
  161. Abstracts
  162. PainData: A clinical pain registry in Denmark
  163. Abstracts
  164. A novel method for investigating the importance of visual feedback on somatosensation and bodily-self perception
  165. Abstracts
  166. Drugs that can cause respiratory depression with concomitant use of opioids
  167. Abstracts
  168. The potential use of a serious game to help patients learn about post-operative pain management – An evaluation study
  169. Abstracts
  170. Modelling activity-dependent changes of velocity in C-fibers
  171. Abstracts
  172. Choice of rat strain in pre-clinical pain-research – Does it make a difference for translation from animal model to human condition?
  173. Abstracts
  174. Omics as a potential tool to identify biomarkers and to clarify the mechanism of chronic pain development
  175. Abstracts
  176. Evaluation of the benefits from the introduction meeting for patients with chronic non-malignant pain and their relatives in interdisciplinary pain center
  177. Observational study
  178. The changing face of acute pain services
  179. Observational study
  180. Chronic pain in multiple sclerosis: A10-year longitudinal study
  181. Clinical pain research
  182. Functional disability and depression symptoms in a paediatric persistent pain sample
  183. Observational study
  184. Pain provocation following sagittal plane repeated movements in people with chronic low back pain: Associations with pain sensitivity and psychological profiles
  185. Observational study
  186. A longitudinal exploration of pain tolerance and participation in contact sports
  187. Original experimental
  188. Taking a break in response to pain. An experimental investigation of the effects of interruptions by pain on subsequent activity resumption
  189. Clinical pain research
  190. Sex moderates the effects of positive and negative affect on clinical pain in patients with knee osteoarthritis
  191. Original experimental
  192. The effects of a brief educational intervention on medical students’ knowledge, attitudes and beliefs towards low back pain
  193. Observational study
  194. The association between pain characteristics, pain catastrophizing and health care use – Baseline results from the SWEPAIN cohort
  195. Topical review
  196. Couples coping with chronic pain: How do intercouple interactions relate to pain coping?
  197. Narrative review
  198. The wit and wisdom of Wilbert (Bill) Fordyce (1923 - 2009)
  199. Letter to the Editor
  200. Unjustified extrapolation
  201. Letter to the Editor
  202. Response to: “Letter to the Editor entitled: Unjustified extrapolation” [by authors: Supp G., Rosedale R., Werneke M.]
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Heruntergeladen am 30.10.2025 von https://www.degruyterbrill.com/document/doi/10.1016/j.sjpain.2017.01.009/html?lang=de
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